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MOStest: Mitchell-Olds \& Shaw Test for the Location of Quadratic Extreme

Description

Mitchell-Olds & Shaw test concerns the location of the highest (hump) or lowest (pit) value of a quadratic curve at given points. Typically, it is used to study whether the quadratic hump or pit is located within a studied interval. The current test is generalized so that it applies generalized linear models (glm) with link function instead of simple quadratic curve. The test was popularized in ecology for the analysis of humped species richness patterns (Mittelbach et al. 2001), but it is more general. With logarithmic link function, the quadratic response defines the Gaussian response model of ecological gradients (ter Braak & Looman 1986), and the test can be used for inspecting the location of Gaussian optimum within a given range of the gradient. It can also be used to replace Tokeshi's test of “bimodal” species frequency distribution.

Usage

MOStest(x, y, interval, ...)
# S3 method for MOStest
plot(x, which = c(1,2,3,6), ...)
fieller.MOStest(object, level = 0.95)
# S3 method for MOStest
profile(fitted, alpha = 0.01, maxsteps = 10, del = zmax/5, ...)
# S3 method for MOStest
confint(object, parm = 1, level = 0.95, ...)

Value

The function is based on glm, and it returns the result of object of glm amended with the result of the test. The new items in the MOStest are:

isHump

TRUE if the response is a hump.

isBracketed

TRUE if the hump or the pit is bracketed by the evaluated points.

hump

Sorted vector of location of the hump or the pit and the points where the test was evaluated.

coefficients

Table of test statistics and their significances.

Arguments

x

The independent variable or plotting object in plot.

y

The dependent variable.

interval

The two points at which the test statistic is evaluated. If missing, the extremes of x are used.

which

Subset of plots produced. Values which=1 and 2 define plots specific to MOStest (see Details), and larger values select graphs of plot.lm (minus 2).

object, fitted

A result object from MOStest.

level

The confidence level required.

alpha

Maximum significance level allowed.

maxsteps

Maximum number of steps in the profile.

del

A step length parameter for the profile (see code).

parm

Ignored.

...

Other variables passed to functions. Function MOStest passes these to glm so that these can include family. The other functions pass these to underlying graphical functions.

Author

Jari Oksanen

Details

The function fits a quadratic curve \(\mu = b_0 + b_1 x + b_2 x^2\) with given family and link function. If \(b_2 < 0\), this defines a unimodal curve with highest point at \(u = -b_1/(2 b_2)\) (ter Braak & Looman 1986). If \(b_2 > 0\), the parabola has a minimum at \(u\) and the response is sometimes called “bimodal”. The null hypothesis is that the extreme point \(u\) is located within the interval given by points \(p_1\) and \(p_2\). If the extreme point \(u\) is exactly at \(p_1\), then \(b_1 = 0\) on shifted axis \(x - p_1\). In the test, origin of x is shifted to the values \(p_1\) and \(p_2\), and the test statistic is based on the differences of deviances between the original model and model where the origin is forced to the given location using the standard anova.glm function (Oksanen et al. 2001). Mitchell-Olds & Shaw (1987) used the first degree coefficient with its significance as estimated by the summary.glm function. This give identical results with Normal error, but for other error distributions it is preferable to use the test based on differences in deviances in fitted models.

The test is often presented as a general test for the location of the hump, but it really is dependent on the quadratic fitted curve. If the hump is of different form than quadratic, the test may be insignificant.

Because of strong assumptions in the test, you should use the support functions to inspect the fit. Function plot(..., which=1) displays the data points, fitted quadratic model, and its approximate 95% confidence intervals (2 times SE). Function plot with which = 2 displays the approximate confidence interval of the polynomial coefficients, together with two lines indicating the combinations of the coefficients that produce the evaluated points of x. Moreover, the cross-hair shows the approximate confidence intervals for the polynomial coefficients ignoring their correlations. Higher values of which produce corresponding graphs from plot.lm. That is, you must add 2 to the value of which in plot.lm.

Function fieller.MOStest approximates the confidence limits of the location of the extreme point (hump or pit) using Fieller's theorem following ter Braak & Looman (1986). The test is based on quasideviance except if the family is poisson or binomial. Function profile evaluates the profile deviance of the fitted model, and confint finds the profile based confidence limits following Oksanen et al. (2001).

The test is typically used in assessing the significance of diversity hump against productivity gradient (Mittelbach et al. 2001). It also can be used for the location of the pit (deepest points) instead of the Tokeshi test. Further, it can be used to test the location of the the Gaussian optimum in ecological gradient analysis (ter Braak & Looman 1986, Oksanen et al. 2001).

References

Mitchell-Olds, T. & Shaw, R.G. 1987. Regression analysis of natural selection: statistical inference and biological interpretation. Evolution 41, 1149--1161.

Mittelbach, G.C. Steiner, C.F., Scheiner, S.M., Gross, K.L., Reynolds, H.L., Waide, R.B., Willig, R.M., Dodson, S.I. & Gough, L. 2001. What is the observed relationship between species richness and productivity? Ecology 82, 2381--2396.

Oksanen, J., Läärä, E., Tolonen, K. & Warner, B.G. 2001. Confidence intervals for the optimum in the Gaussian response function. Ecology 82, 1191--1197.

ter Braak, C.J.F & Looman, C.W.N 1986. Weighted averaging, logistic regression and the Gaussian response model. Vegetatio 65, 3--11.

See Also

The no-interaction model can be fitted with humpfit.

Examples

Run this code
## The Al-Mufti data analysed in humpfit():
mass <- c(140,230,310,310,400,510,610,670,860,900,1050,1160,1900,2480)
spno <- c(1,  4,  3,  9, 18, 30, 20, 14,  3,  2,  3,  2,  5,  2)
mod <- MOStest(mass, spno)
## Insignificant
mod
## ... but inadequate shape of the curve
op <- par(mfrow=c(2,2), mar=c(4,4,1,1)+.1)
plot(mod)
## Looks rather like log-link with Poisson error and logarithmic biomass
mod <- MOStest(log(mass), spno, family=quasipoisson)
mod
plot(mod)
par(op)
## Confidence Limits
fieller.MOStest(mod)
confint(mod)
plot(profile(mod))

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